Methods and apparatus to categorize media impressions by age

ABSTRACT

An example apparatus includes a memory management unit (MMU) to store audience member records in a first block of memory, the audience member records including attribute-value pairs representative of database subscriber activity data of corresponding audience members subscribed to a database proprietor. The MMU to split the audience member records from an initial node into child nodes based on comparisons of first ones of the attribute-value pairs of the audience member records to a first value threshold. When an arithmetic logic unit (ALU) determines that a quantity of ones of the audience member records does not satisfy a minimum leaf size, store a terminal node value in the second block of the memory to indicate the first child node is associated with one age category. When the ALU determines that the quantity of the ones of the audience member records satisfies the minimum leaf size, split the first child node into second child nodes, the audience member records in the first child node to be: (1) assigned to corresponding ones of the second child nodes based on comparisons of second ones of the attribute-value pairs of the audience member records to a second value threshold, and (2) processed further to create terminal nodes. Generate an age-correction model based on the terminal nodes to facilitate correcting a database subscriber age characteristic associated with a media impression that is logged by a server of the database proprietor based on a network communication transmitted by a client device to report to the server of the database proprietor that media was accessed via the client device.

CROSS REFERENCE TO RELATED APPLICATIONS

This patent arises from a continuation of U.S. patent application Ser.No. 14/928,468, filed Oct. 30, 2015, now U.S. Pat. No. ______, which ishereby incorporated herein by reference in its entirety.

FIELD OF THE DISCLOSURE

This disclosure relates generally to audience membership, and, moreparticularly, to methods and apparatus to categorize media impressionsby age.

BACKGROUND

Audience measurement entities measure exposure of audiences to mediasuch as television, music, movies, radio, Internet websites, streamingmedia, etc. The audience measurement entities generate ratings based onthe measured exposure. Ratings are used by advertisers and/or marketersto purchase advertising space and/or design advertising campaigns.Additionally, media producers and/or distributors use the ratings todetermine how to set prices for advertising space and/or to makeprogramming decisions.

Techniques for monitoring user access media have evolved significantlyover the years. Some prior systems perform such monitoring primarilythrough server logs. In particular, entities serving media on theInternet can use such prior systems to log the number of requestsreceived for their media at their server.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates an example system constructed in accordance with theteachings of this disclosure.

FIG. 2 illustrates an example audience member record used by the agemodeler of FIGS. 1 to generate the age correction model.

FIG. 3 illustrates an implementation of the example age modeler of FIG.1 to generate the age correction model.

FIGS. 4A and 4B are a flow diagrams of example machine readableinstructions that may be executed to implement the example age modelerof FIGS. 1 and/or 3 to generate the age correction model.

FIG. 5 is a flow diagram of example machine readable instructions thatmay be executed to implement the example weight calculator of FIG. 3 toassign weights to audience member records.

FIG. 6 is a block diagram of an example processor system that mayexecute any of the machine readable instructions represented by FIGS.4A, 4B, and/or 5 to implement the apparatus of FIGS. 1 and/or 3.

Wherever possible, the same reference numbers will be used throughoutthe drawing(s) and accompanying written description to refer to the sameor like parts.

DETAILED DESCRIPTION

Examples disclosed herein may be used to generate age correction modelsthat correct age misattribution in impression records. To measureaudiences, an audience measurement entity (AME) may use instructions(e.g., Java, java script, or any other computer language or script)embedded in media to collect information indicating when audiencemembers are accessing media on a computing device (e.g., a computer, alaptop, a smartphone, a tablet, etc.). Media to be monitored is taggedwith these instructions. When a device requests the media, both themedia and the instructions are downloaded to the client. Theinstructions cause information about the media access to be sent fromthe device to a monitoring entity (e.g., the AME) and/or a databaseproprietor (e.g., Google, Facebook, Experian, Baidu, Tencent, etc.).Examples of tagging media and monitoring media through theseinstructions are disclosed in U.S. Pat. No. 6,108,637, issued Aug. 22,2000, entitled “Content Display Monitor,” which is incorporated byreference in its entirety herein.

Additionally, the instructions cause one or more user and/or deviceidentifiers (e.g., an international mobile equipment identity (IMEI), amobile equipment identifier (MEID), a media access control (MAC)address, an app store identifier, an open source unique deviceidentifier (OpenUDID), an open device identification number (ODIN), alogin identifier, a username, an email address, user agent data,third-party service identifiers, web storage data, document object model(DOM) storage data, local shared objects also referred to as “Flashcookies”), browser cookies, an automobile vehicle identification number(VIN), etc.) located on the computing device to be sent to a partnereddatabase proprietor to identify demographic information (e.g., age,gender, geographic location, race, income level, education level,religion, etc.) for the audience member of the computing devicecollected via a user registration process. For example, an audiencemember may be viewing an episode of “Documentary Now” in a mediastreaming app on a smartphone. In that instance, in response toinstructions executing within the app, a user/device identifier storedon the smartphone is sent to the AME and/or a partner databaseproprietor to associate the instance of media exposure (e.g., animpression) to corresponding demographic information of the audiencemember. The database proprietor can then send logged demographicimpression data to the AME for use by the AME in generating, forexample, media ratings and/or other audience measures.

In some examples, the partner database proprietor does not provideindividualized demographic information (e.g., user-level demographics)in association with logged impressions. Instead, in some examples, thepartnered database proprietor provides aggregate demographic impressiondata (sometimes referred to herein as “aggregate census data”). Forexample, the aggregate demographic impression data provided by thepartner database proprietor may show that fifteen thousand males age18-23 watched the episode of “Documentary Now” in the last seven daysvia computing devices. However, the aggregate demographic informationfrom the partner database proprietor does not identify individualpersons (e.g., is not user-level data) associated with individualimpressions. In this manner, the database proprietor protects theprivacies of its subscribers/users by not revealing their identitiesand, thus, user-level media access activities, to the AME.

The AME uses this aggregated demographic information to calculateratings and/or other audience measures for corresponding media. However,during the process of registering with the database proprietor, asubscriber may lie or may otherwise provide inaccurate demographicinformation. For example, during registration, the subscriber mayprovide an inaccurate age or location. These inaccuracies cause errorsin the aggregate demographic information from the partner databaseproprietor, and can lead to errors in audience measurement. To combatthese errors, the AME recruits panelist households that consent tomonitoring of their exposure to media. During the recruitment process,the AME obtains detailed demographic information from the members of thepanelist household. While the self-reported demographic information(e.g., age, etc.) reported to the database proprietor is generallyconsidered to be potentially inaccurate, the demographic informationcollected from the panelist (e.g., via a survey, etc.) by the AME isconsidered highly accurate. As used herein, the term “true age” refersto age information collected from the panelist by the AME.

The AME also retrieves activity data from the partnered databaseproprietor. The database proprietor activity data includes self-reporteddemographic data (e.g., age, high school graduation year, profession,marital status, etc.), subscriber metadata (e.g., number of connections,median age of connections, etc.), and subscriber use data (e.g.,frequency of login, frequency of posts, devices used to login, privacysettings, etc.). Examples of retrieving the activity data from thepartnered database subscriber(s) are disclosed in U.S. patentapplication Ser. No. 14/864,300, filed Sep. 24, 2015, entitled “Methodsand Apparatus to Assign Demographic Information to Panelists,” which isincorporated by reference in its entirety herein.

The AME develops age correction model(s) (e.g., decision tree models,regression tree models, etc.) to assign an age category (e.g., anage-based demographic bucket) and/or an age category probability densityfunction (PDF) to an audience member corresponding to a loggedimpression. The PDFs indicate probabilities that the audience memberfalls within certain ones of the respective age categories. The agecorrection models are generated using the database proprietor activitydata of panelists and the detailed demographic information supplied bythe panelist to the AME. The database proprietor activity data isorganized into attribute-value pairs. In the attribute-value pairs, theattribute is a category in the activity data (e.g., marital status, postfrequency, reported age, etc.) and the value is the corresponding value(e.g., single, five times per week, twenty seven, etc.) of theattribute. For example, an attribute-value pair may be[active_in_last_7_days, true].

In some examples, to generate the model, one of the attributes isselected with a corresponding threshold value. For example, the selectedattribute-threshold pair may be [login_frequency, three times per week].The audience member records are split into two portions based on theattribute-threshold pair. For example, the audience member records maybe divided between the audience members records corresponding to loginfrequencies of greater than three times per week and the audiencemembers records corresponding to login frequencies of less than or equalto three times per week. Child nodes are created with each portion ofthe audience member records. For example, a child node is created forthe audience members records corresponding to login frequencies ofgreater than three times per week, and a child node is created for theaudience members records corresponding to login frequencies of less thanor equal to three times per week. For each child node, a determinationis made, based on a minimum leaf size, whether (i) to designate thechild node as an intermediate node and to split audience member recordsassigned to the intermediate node into additional child nodes, or (ii)to designate the child node as a terminal node. In some examples, thechild node is designated a terminal node if the audience member recordsassigned to the child node are associate with the same age category.This process continues until there are no child nodes, all audiencemembers in a child node are in the same age category, or the modelsatisfies (e.g., is greater than) a length threshold. The terminal nodesare assigned age categories or age-category probability densityfunctions based on the true ages of audience members assigned to thatterminal node.

As disclosed below, before generating the age correction model, theaudience member records in the training data set sorted into agecategories (sometimes referred to as “age-based demographic groups”and/or “demographic buckets”). For example, age categories may bedefined for ages 7-12, 13-17, 18-24, 25-34, 35-44, 45-54, 55-64, and65+. Traditionally, because of the difficulty of recruiting panelists incertain age categories (e.g., the 7-12 age category, the 55-64 agecategory, the 65+age category, etc.), some age categories areunderrepresented by the audience member records in the training set.Underrepresented age categories may not contribute to the model enoughso that output of the model is influenced by the underrepresented agecategories.

As disclosed below, before generating the age correction model, theaudience member records in the training set are assigned weights basedon their corresponding age category. The example assigned weight for theaudience member records in one of the age categories is inverselyproportional to a quantity of the audience member records in acorresponding one of the age categories. In some examples, the agecategories with a quantity of the audience member records in thetraining data set that satisfy (e.g., greater than or equal to) a firstweighing threshold are assigned a neutral weight. In some such examples,the neutral weight is one. In some examples, the age categories with thequantity of the audience member records that satisfy (e.g., are lessthan or equal to) a second weighing threshold are assigned a maximumweight. In some such examples, the maximum weight is between 1.1 and1.5. In some examples, the age categories with the quantity of theaudience member records that is between the first weighing threshold andthe second weighing threshold are assigned a weight between the neutralweight and the maximum weight.

In the disclosed examples, while generating the age correction model,when determining whether to split a child node, the weights for theaudience member records assigned to the child node are added togetherand compared to the minimum leaf size. If the summed weights satisfy(e.g., greater than) the minimum leaf size, the child node is split intomore child nodes based on another attribute-threshold pair. Otherwise,if the summed weights do not satisfy (e.g., less than or equal to) theminimum leaf size, the child node becomes a terminal node. The minimumleaf size is determined based on the number of audience member recordsin the training set. The minimum leaf size is chosen to prevent bothoverfitting, which causes the terminal nodes to be too specific, andunderfitting, which causes the terminal nodes to be too general.

When the branches of the age correction model terminate in terminalnodes, the probability density functions assigned to the terminal nodesare characterized. For example, a terminal node may be associatedaudience member records from the second training set corresponding totwenty-five audience member records associated with the 18-24 agecategory, fifty-seven audience member records associated with the 25-34age category, and eighteen audience member records associated with the35-44 age category. Examples to characterize the probability densityfunctions assigned to the terminal nodes based on associated audiencemember records associated with the terminal nodes are disclosed in U.S.Pat. No. 9,092,797, issued Jul. 28, 2015, entitled “Methods andApparatus to Analyze and Adjust Demographic Information,” which isincorporated by reference in its entirety.

The model is used to correct inaccurate age information provided by thesubscribers of the database proprietor. When an impression is logged fora subscriber of the database proprietor, the activity data associatedwith that subscriber is processed by the model to assign a corrected agevalue and/or a probability density function to the impression based onwhich of the terminal nodes the activity data is assigned. Examples toassign a corrected age value and/or a probability density function tothe impression based on the model are disclosed in U.S. patentapplication Ser. No. 14/604,394, filed Jan. 23, 2015, entitled “Methodsand Apparatus to Correct Age Misattribution in Media Impressions,” whichis incorporated by reference in its entirety.

FIG. 1 illustrates an example system 100 to generate an age correctionmodel used to be used to correct age information associated withdemographic impressions logged by a database proprietor 102. In theillustrated example, the AME 104 provides an AME identifier (AME ID)106, a collector 108, and a database proprietor identifier (DPID)extractor 110 to a computing device 112 (e.g., a desktop, a laptop, atablet, a smartphone, etc.) associated with a panelist household. Forexample, the AME 104 may provide the collector 108, the DPID extractor110, and the AME ID 106 via a registration website. In some examples,the collector 108, the DPID extractor 110 are performed by instructions(e.g., Java, java script, or any other computer language or script)embedded in the registration website, or any other suitable website. Insome examples, the AME ID 106 is a cookie or is encapsulated in a cookieset in the computing device 112 by the AME 104. Alternatively, the AMEID 106 could be any other user and/or device identifier (e.g., an emailaddress, a user name, etc.). In any case, the example AME ID 106 is analphanumeric value that the AME 104 uses to uniquely identify thepanelist household.

In the illustrated example, member(s) of the panelist household (e.g. ahead of household) provide(s) detailed demographic information 114(e.g., true age, ethnicity, first name, middle name, gender, householdincome, employment status, occupation, rental status, level ofeducation, etc.) of the member(s) of the panelist household. In theillustrated example, the detailed demographic information 114 isprovided via the computing device 112 through the registration website,or any other suitable website. The example computer device 112 sends anexample registration message 116 that includes the AME ID 106 and thedetailed demographic information 114. Alternatively, in some examples,AME 104 collects the detailed demographic information 114 though othersuitable means, such as a telephone survey, a paper survey, or anin-person survey, etc.

In the illustrated example, when a member of the panelist household usesthe computing device 112 to visit a website and/or use an app associatedwith a database proprietor 102, the database proprietor 102 sets orotherwise provides, on the computing device 112, a panelist DPID 118associated with subscriber credentials (e.g., user name and password,etc.) used to access the website and/or the app. In some examples, thepanelist DPID 118 is a cookie or is encapsulated in a cookie.Alternatively, the panelist DPID 118 could be any other user and/ordevice identifier. The example DPID extractor 110 extracts the DPID 118(e.g., from a cookie, etc.). The example collector 108 collects thepanelist DPIDs 118 on the computing device 112 and sends an example IDmessage 120 to the example AME 104. In the illustrated example, the IDmessage 120 includes the extracted panelist DPID 118 and the AME ID 106corresponding to the panelist household. In some examples, the DPIDextractor 110 remembers the panelist DPIDs 118 that have been extractedand sends the ID message 120 when a new panelist DPID 118 has beenextracted.

In the illustrated example, the AME 104 includes an example panelistmanager 122, an example panelist database 124, an example demographicretriever 126, an example age modeler 128, and an example age corrector130. The example panelist manager 122 receives the registration message116 and the ID message(s) 120 from the computing device 112. Based onthe registration message 116 and the ID message(s) 120, the panelistmanager 122 generates a panelist household record 132 that associatesthe AME ID 106 to the detailed demographic information 114 and theDPID(s) 118 of the members of the panelist household. The examplepanelist manager 122 stores the example panelist household record 132 inthe panelist database 124.

The example demographic retriever 126 is structured to retrieve databaseproprietor activity data 134 from the example database proprietor 102.In the illustrated example, the database proprietor 102 provides anapplication program interface (API) that provides access to a subscriberdatabase 136 based on DPIDs (e.g., the panelist DPIDs 118, etc.). Theexample subscriber database 136 includes the database proprietoractivity data 134 of the subscribers to the database proprietor 102. Theexample demographic retriever 126 sends queries 138 to the databaseproprietor 102 that include the DPIDs 118 associated with the examplepanelist household records 132 in the example panelist database 124. Inthe illustrated example, in response to the queries 138, the databaseproprietor 102 sends query responses 140 to the AME 106. The examplequery responses 140 includes the database proprietor activity data 134corresponding to the panelist DPID 118 of the example query 138. Theexample demographic retriever 126 stores the database proprietoractivity data 134 in association with the corresponding panelisthousehold record 132 in the panelist database 124.

The example age modeler 128 generates an example age correction model142 based on the panelist household records 132 in the example panelistdatabase 124. Examples for generating the age correction model 142 aredisclosed below in connection with FIG. 2. To generate the agecorrection model 142, the age modeler 128 splits the panelist householdrecords 132 into audience member records that each represent a member ofone of the panelist households. For example, a panelist household mayhave four members (e.g., a father, a mother, a son, and a daughter,etc.). In such an example, the age modeler 128 creates four audiencemember records, with each of the audience member records including aportion of the detailed demographic data 114 and the database proprietoractivity data 134 corresponding to the respective member of the panelisthousehold.

The example age modeler 128 separates the audience member records into atraining set and a validation set. In some examples, 80 % of theaudience member records are assigned to the training set, and theremaining 20 % of the audience member records are assigned to thevalidation set. In some such examples, the multiple training sets andmultiple validation sets are generated. In some example, the audiencemember record are randomly or pseudo-randomly assigned to either thetraining set or the validation set. The example age modeler 128 assignsweights (w) to the audience member records in the training set.Initially, the audience member records in the training set are dividedin to age categories (e.g., ages 7-13, ages 14-17, ages 18-21, etc.)based on the true ages associated with the audience member records. Theweight assigned to audience member records in one of the age categoriesis based on a quantity (n_(g)) of audience member records in that agecategory. The example age modeler 128 then generates the age correctionmodel 142 based on decision tree generation techniques or regressiontree generation techniques using the weighted audience member records.

In some examples, when the AME 104 has access to database subscriberactivity data 134 associated with individualized logged impressions, theage corrector 130 receives the age correction model 142 from the agemodeler 128. In some such examples, the example age corrector 130 usesthe age correction model 142 to assign an age-based PDF to theindividualized logged impression. The age-based PDF definesprobabilities that the real age of the subscriber corresponding to thelogged impression is within certain age categories. For example, theage-based PDF may indicate that the probability of the subscriberassociated with the logged impression being in the 18-21 age range is11.6%, the probability of the subscriber being in the 22-27 age range is44.5%, the probability of the subscriber being in the 28-33 age range is36.7%, and the probability of the subscriber being in the 34-40 agerange is 7.2%.

Alternatively, in some examples, the AME 104 sends the age correctionmodel 142 to the database proprietor 102. In some such examples, whenthe database proprietor 102 logs an impression associated with asubscriber, the database proprietor 102 uses the age correction model142 to assign the age based PDF to the logged impression. In some suchexamples, because the age based PDFs are fixed through the generation ofthe age correction model 142, the database proprietor 102 assigns a PDFidentifier that identifies a particular age based PDF to the loggedimpression. In some such examples, the database proprietor 102aggregates the logged impressions based on the PDF identifier. Forexample, the aggregate logged impression data from the databaseproprietor 102 may indicate that two thousand subscribers assigned tothe “M7” age-based PDF watched season five, episode two of “Portlandia”in the last seven days. In such an example, the “M7” age-based PDF maycorrespond to probability of the subscribers associated with theaggregate logged impression data being in the 18-21 age category is3.2%, the probability of the subscribers being in the 22-27 age categoryis 86.9%, the probability of the subscribers being in the 28-33 agecategory is 9.4%, and the probability of the subscribers being in the34-40 age category is 0.5%. In such an example, of the two thousandsubscribers, the AME 104 would assign 64 subscribers to the 18-21 agecategory, 1738 subscribers to the 22-27 age category, 188 subscribers tothe 28-33 age category, and 10 subscribers to the 34-40 age category.

FIG. 2 illustrates an example audience member record 202 generated bythe age modeler 128 of FIGS. 1 to produce the age correction model 142.The example age modeler 128 generates the example audience member record202 based the on detail demographic data 114 (FIG. 1) retrieved from thecomputing device 112 of a panelist, and the database proprietorsubscriber activity data 134 retrieved from the database proprietor 102(FIG. 1). The audience member record 202 corresponds to a member of apanelist household. For example, if a panelist household has threemembers, three audience member records 202 are generated for thatpanelist household. In the illustrated example, the audience memberrecord 202 includes pairs of attributes 204 and values 206. The exampleattributes 204 include data categories that are collected by the exampledatabase proprietor 102 and/or the example AME 104 (FIG. 1). A firstportion 208 of the attributes 204 and the corresponding values 206 isderived from the detail demographic data 114. For example, a pair of anattribute 204 and a value 206 that is derived from the detaildemographic data 114 may be “true age” and “36,” respectively. A secondportion 210 of the attributes 204 and the corresponding values 206 isderived from the database proprietor subscriber activity data 134associated with the member of the panelist household. For example, apair of an attribute 204 and a value 206 that is derived from databaseproprietor subscriber activity data 134 may be “stated age” and “35,”respectively.

FIG. 3 illustrates an implementation of the example age modeler 128 ofFIG. 1 to generate the age correction model 142. The example age modeler128 includes an example record generator 302, an example weightcalculator 304, and an example model builder 306. The example agemodeler 128 is structured to generate an age correction model 142 thatcompensates for underrepresented age categories from within the membersof the panelist households.

In the illustrated example, the record generator 302 generates theaudience member records 202 (FIG. 2) based on the panelist householdrecords 132 in the panelist database 124. To generate the audiencemember records 202, the example record generator 302 retrieves thepanelist household records 132 from the panelist database 124. Theexample panelist household record 132 includes the AME ID 106corresponding to the panelist households, the detailed demographicinformation 114, and one or more sets of database subscriber activitydata 134 (e.g., a set of database subscriber activity data 134 for eachmember of the panelist household). The example record generator 302randomly or pseudo-randomly divides the generated audience memberrecords 202 into a training set and a validation set.

The example weight calculator 304 receives or otherwise retrieves thetraining set from the example record generator 302. The weightcalculator 304 sorts the audience records in the training set into agecategories based on the true ages. To determine the weights assigned tothe audience member records 202, the example weight calculator 304categorizes the age categories based on a quantity (n_(g)) of theaudience member records 202 in the respective age categories.Alternatively, in some examples (e.g., when regression analysis isused), to determine the weights assigned to one of the audience memberrecords 202, the example weight calculator 304 calculates the quantity(n_(g)) of the audience member records 202 based on the true age of theone of the audience member records 202 and other ones of the audiencemember records 202 within a target error level (e_(t)) of that true age.For example, if the true age associated with the audience member record202 is 42 years old and the target error level (e_(t)) is two years, thequantity (n_(g)) of the audience member records 202 is calculated withaudience member records 202 with true ages that range from 40-44 yearsold.

Additionally, the example weight calculator 304 determines the firstweighing threshold (th_(n)) and the second weighing threshold (th_(vl)).The example weight calculator 304 calculates the first weighingthreshold (th_(n)) using Equation 1 below.

th _(n) =m _(ls) *c   Equation 1

In Equation 1 above, mi is the minimum leaf size, and c is a constant.In some examples c is equal to a value between 1.1 and 1.5. The value ofc is configurable. A larger value of c increases the number of agecategories that are considered to be underrepresented and increases theweight assigned to underrepresented age categories. For example, if theminimum leaf size (m_(ls)) is 30 audience member records 202 and theconstant (c) is 1.2, the first weighing threshold is 36 (30*1.2). Insuch an example, if one of the age categories has 36 or less associatedaudience member records, the one of the age categories is considered tobe underrepresented. The example weight calculator 304 calculates asecond weighing threshold (th_(vl)) using Equation 2 below.

$\begin{matrix}{{th}_{vl} = \frac{m_{ls}*c}{w_{m\; {ax}}}} & {{Equation}\mspace{14mu} 2}\end{matrix}$

In Equation 2 above, w_(max) is a maximum weight to assign to the agecategories. Changing the example maximum weight (w_(max)) changes theinfluence that underrepresented age categories have on the agecorrection model 142. For example, if the minimum leaf size (m_(ls)) is30 audience member records 202, the constant (c) is 1.2, and the maximumweight (w_(max)) is 2, the second weighing threshold is 18 (30*1.2/2).

The example weight calculator 304 compares the quantities (n_(g)) of theaudience member records 202 in the respective age categories to thefirst and second weighing thresholds. In the illustrative example, ifthe quantity (n_(g)) of the audience member records 202 in the agecategory of interest satisfies (e.g. is greater than or equal to) thefirst weighing threshold (th_(n)), the weight calculator 304 assigns aneutral weight (e.g., one) to the audience member records 202 in thatage category. For example, if there are 353 audience member records 202in the 45-49 age category and the first weighing threshold (th_(n)) is36, the weight calculator 304 assigns the neutral weight to therespective 353 audience member records 202. If the quantity (n_(g)) ofthe audience member records 202 in the age category satisfies (e.g., isless than or equal to) the second weighing threshold (th_(vl)), theweight calculator assigns the maximum weight (w_(max)) to the audiencemember records 202 in that age category. For example, if there are 10audience member records 202 in the 7-13 age category and the secondweighing threshold (th_(vl)) is 18, the weight calculator 304 assignsthe maximum weight (w_(max)) to the respective 10 audience memberrecords 202.

If the quantity (n_(g)) of the audience member records 202 in the agecategory of interest does not satisfy either of the first weighingthreshold (th_(n)) or the second weighing threshold (th_(vl)), theweight calculator 304 assigns a weight to the audience member records202 in the age category using Equation 3 below.

$\begin{matrix}{w = \frac{m_{ls}*c}{n_{g\;}}} & {{Equation}\mspace{14mu} 3}\end{matrix}$

In Equation 3 above, w is the weight to be assigned to the audiencemember records 202 in the particular age category. For example, if thefirst weighing threshold (th_(n)) is 36, the second weighing threshold(th_(vl)) is 18, and the quantity (n_(g)) of the audience member records202 in the age category is 28, the weight calculator 304 assigns aweight (w) of 1.3 (30*1.2/28) to the respective 28 audience memberrecords 202.

The example model builder 306 receives or otherwise retrieves theweighted audience member records 202 from the weight calculator 304. Theexample model builder 306 uses the weighted audience member records 202to generate a decision tree or a regression tree. Initially, to generatethe age correction model 142, the model builder 306 selects an attribute(e.g., one of the attributes 204 of FIG. 2) and a corresponding valuethreshold. In some examples, the model builder 306 selects the attribute204 and the corresponding value threshold based on (i) maximizingentropy and, (ii) for each of the age categories, maximizing an averagehomogeneity of the audience member records assigned to the child nodes.A minimum entropy (e.g., 0.0) means that all the audience member recordswould be assigned to the same child node based on the selected attribute204 and the corresponding value threshold. A maximum entropy (e.g., 1.0)means that 50% of the audience member records would be assigned to oneof the child nodes and 50% of the audience member records would assignedto the other one of the child nodes. A minimum homogeneity for the agecategories means that 50% the audience member records associated withthe age category are assigned of one of the child nodes, and 50% of theaudience member records associated with the age category are assigned tothe other one of the child nodes. A maximum homogeneity means that allof the audience member records associated with an age category areassigned to the same child node.

The example model builder 306 generates two child nodes. The examplemodel builder 306 assigns the audience member records 202 that satisfy(e.g., are greater than or equal to) the selected value threshold to oneof the child nodes. Additionally, the example model builder 206 assignsthe audience member records 202 that don't satisfy (e.g. are less than)the selected value threshold to the other one of the child nodes. Forexample, the selected attribute 204 is “number of connections” and thevalue threshold is 215, the audience member records 202 with a value(e.g., the value 206 of FIG. 2) associated with the “number ofconnections” attribute 204 greater than or equal to 215 is assigned toone of the child nodes.

Subsequently, the model builder 306 analyzes the child nodes until thereare no more child nodes to be analyzed. To start analyzing a child node,the example model builder 306 determines whether the child node is to be(i) designated as an intermedia node and split into two additional childnodes, or (ii) designated as a terminal node. To determine whether thechild node is to be designated as an intermedia node and split into twoadditional child nodes, the example model builder 306 determines aneffective quantity (n_(e)) of the audience member records 202 at thechild node using Equation 4 below.

$\begin{matrix}{n_{e} = {\sum\limits_{i = 1}^{j}{rw}_{i}}} & {{Equation}\mspace{14mu} 4}\end{matrix}$

In Equation 4 above, j is the quantity of the audience member records202 assigned to the child node being analyzed, and rw_(i) is theassigned weight of the ith audience member record 202. An example ofaudience member records 202 assigned to a child node is shown on Table 1below.

TABLE 1 EXAMPLE AUDIENCE MEMBER RECORDS WITH ASSOCIATED WEIGHTS Numberof Audience Member Record(s) Weight  1-35 1 36-42 1.3 43-49 1.6 50 1.851, 52 2In the example shown on Table 1 above, the effective quantity (n_(e)) ofaudience member records 202 is 61.1((35*1)+(7*1.3)+(7*1.6)+(1*1.8)+(2*2)).

In the illustrated example of FIG. 3, the model builder 306 determinesthat the child node is to be designated an intermediate node and splitinto two additional child nodes if the effective quantity (n_(e)) of theaudience member records 202 satisfies Equation 5 below.

n _(e)>2*m _(ls)   Equation 5

For example, if the effective quantity (n_(e)) of the audience memberrecords 202 is 61.1 and the minimum leaf size (m_(ls)) is 30, the modelbuilder 306 determines to split the child node into two additional childnodes (61.1>2*30). To split the child node into additional child nodes,the example model builder 206 selects an attribute 204 and a valuethreshold (e.g. based on a maximum entropy value) and assigns theaudience member records 202 to the respective new child nodes based onthe selected attribute 204 and the selected value threshold. When thechild nodes have been analyzed (e.g., each branch of the tree ends in aterminal node), the model builder 306 designates the decision tree orthe regression tree to be the age-correction model 142.

The example model builder 306 receives or otherwise retrieves thevalidation set from the record generator 302. The model builder 306applies the audience member records 202 in the validation set to theage-correction model 142 so that the audience member records 202 areassigned to the respective terminal nodes. After the audience memberrecords 202 are assigned to the respective terminal nodes, the modelbuilder 306 determines an accuracy of the age correction model 142. Insome examples, the accuracy is based on comparing the audience memberrecords 202 of the validation set assigned to the terminal node to theage-based PDF corresponding to the terminal node. An example todetermine the accuracy of one of the terminal nodes is shown in Table 2below.

TABLE 2 EXAMPLE AGE-BASED PDF FOR A TERMINAL NODE AND EXAMPLE AUDIENCEMEMBER RECORDS ASSIGNED TO THE TERMINAL NODE Age Category 7-13 14-2122-34 35-44 45-64 65+ Age-Based PDF 0% 5% 15% 70% 10% 0% (Predicted TrueAge) Validation Set 0% 10% 23% 57% 8% 2% (Actual True Age)In Table 2 above, 15% of the audience member records 202 in thevalidation set are not classified correctly by the age-correction model142. For example, according to the age-based PDF, 5% of the audiencemember records 202 assigned to the particular terminal node are to beclassified in the 14-21 age category. However, in the example, 10% ofthe audience member records 202 with a true age between 14 and 21 areassigned to the terminal node by the age-correction model 142. In someexamples, the accuracy of the age-correction model 142 is determined bycalculating a maximum error, a mean error and/or a mode error for theterminal nodes in the age-correction model 142. In some examples, if themaximum error, the mean error and/or the mode error is/are too large,the model builder 306 regenerates the age-correction model 142 with adifferent training set and/or adjusts the minimum leaf size (m_(ls)),the constant (c), and/or the maximum weight (w_(max)).

In some examples, the model builder 306 generates the age correctionmodel 142 to predict the age of the audience member instead ofpredicting the age category PDF for the audience member (e.g., throughregression analysis). In some such examples, the quantity (n_(g)) of theaudience member records 202 in Equation 3 above is defined as thequantity of the audience member records 202 within a distance of thetarget error level (e_(t)) of the true age of the audience member whoseweight (w) is being calculated.

While an example manner of implementing the example age modeler 128 ofFIG. 1 is illustrated in FIG. 3, one or more of the elements, processesand/or devices illustrated in FIG. 3 may be combined, divided,re-arranged, omitted, eliminated and/or implemented in any other way.Further, the example record generator 302, the example weight calculator304, the example model builder 306, and/or, more generally, the exampleage modeler 128 of FIG. 1 may be implemented by hardware, software,firmware and/or any combination of hardware, software and/or firmware.Thus, for example, any of the example record generator 302, the exampleweight calculator 304, the example model builder 306, and/or, moregenerally, the example age modeler 128 could be implemented by one ormore analog or digital circuit(s), logic circuits, programmableprocessor(s), application specific integrated circuit(s) (ASIC(s)),programmable logic device(s) (PLD(s)) and/or field programmable logicdevice(s) (FPLD(s)). When reading any of the apparatus or system claimsof this patent to cover a purely software and/or firmwareimplementation, at least one of the example record generator 302, theexample weight calculator 304, and/or the example model builder 306is/are hereby expressly defined to include a tangible computer readablestorage device or storage disk such as a memory, a digital versatiledisk (DVD), a compact disk (CD), a Blu-ray disk, etc. storing thesoftware and/or firmware. Further still, the example age modeler 128 ofFIG. 1 may include one or more elements, processes and/or devices inaddition to, or instead of, those illustrated in FIG. 3, and/or mayinclude more than one of any or all of the illustrated elements,processes and devices.

Flowcharts representative of example machine readable instructions forimplementing the age modeler 128 of FIGS. 1 and 3 are shown in FIGS. 4A,4B, and 5. In this example, the machine readable instructions compriseprogram(s) for execution by a processor such as the processor 612 shownin the example processor platform 600 discussed below in connection withFIG. 6. The program(s) may be embodied in software stored on a tangiblecomputer readable storage medium such as a CD-ROM, a floppy disk, a harddrive, a digital versatile disk (DVD), a Blu-ray disk, or a memoryassociated with the processor 612, but the entire program and/or partsthereof could alternatively be executed by a device other than theprocessor 612 and/or embodied in firmware or dedicated hardware.Further, although the example program(s) is/are described with referenceto the flowcharts illustrated in FIGS. 4A, 4B, and 5, many other methodsof implementing the example age modeler 128 may alternatively be used.For example, the order of execution of the blocks may be changed, and/orsome of the blocks described may be changed, eliminated, or combined.

As mentioned above, the example processes of FIGS. 4A, 4B, and 5 may beimplemented using coded instructions (e.g., computer and/or machinereadable instructions) stored on a tangible computer readable storagemedium such as a hard disk drive, a flash memory, a read-only memory(ROM), a compact disk (CD), a digital versatile disk (DVD), a cache, arandom-access memory (RAM) and/or any other storage device or storagedisk in which information is stored for any duration (e.g., for extendedtime periods, permanently, for brief instances, for temporarilybuffering, and/or for caching of the information). As used herein, theterm tangible computer readable storage medium is expressly defined toinclude any type of computer readable storage device and/or storage diskand to exclude propagating signals and to exclude transmission media. Asused herein, “tangible computer readable storage medium” and “tangiblemachine readable storage medium” are used interchangeably. Additionallyor alternatively, the example processes of FIGS. 4A, 4B, and 5 may beimplemented using coded instructions (e.g., computer and/or machinereadable instructions) stored on a non-transitory computer and/ormachine readable medium such as a hard disk drive, a flash memory, aread-only memory, a compact disk, a digital versatile disk, a cache, arandom-access memory and/or any other storage device or storage disk inwhich information is stored for any duration (e.g., for extended timeperiods, permanently, for brief instances, for temporarily buffering,and/or for caching of the information). As used herein, the termnon-transitory computer readable medium is expressly defined to includeany type of computer readable storage device and/or storage disk and toexclude propagating signals and to exclude transmission media. As usedherein, when the phrase “at least” is used as the transition term in apreamble of a claim, it is open-ended in the same manner as the term“comprising” is open ended.

FIGS. 4A and 4B are a flow diagrams of example machine readableinstructions that may be executed to implement the example age modeler128 of FIGS. 1 and/or 3 to generate the age correction model 142 (FIGS.1 and 3). Initially, the example record generator 302 (FIG. 3) generatesaudience member records 202 (FIG. 2) based on the detailed demographicinformation 114 (FIGS. 1 and 3) and database subscriber activity data134 stored in the panelist database 124 (FIGS. 1 and 3) (block 402). Insome examples, the example record generator 302 may execute instructionsthat cause a memory management unit (e.g., the memory management unit(MMU) 636 of FIG. 6) to load the detailed demographic information 114and the database subscriber activity data 134 into volatile memory(e.g., the volatile memory 614 of FIG. 6) and to generate the audiencemember records 202 in the volatile memory 614 by merging portions of thedetailed demographic information 114 with the database subscriberactivity data 134. The example record generator 302 organizes theaudience member records 202 generated at block 402 into a training setand a validation set (block 404). In some examples, the record generator302 randomly or pseudo-randomly assigns the audience member records 202to either the training set or the validation set. In some examples, theexample record generator 302 may execute instructions that cause thememory management unit 636 to allocate a first block of memory to storethe training set and a second block of memory to store the validationset.

The example weight calculator 304 (FIG. 3) selects an age category(block 406). For example, the weight calculator 304 may select the 7-13age category. In some examples, the weight calculator 304 executesinstructions that cause the memory management unit 636 to place into aregister (e.g., one of the registers 635 of FIG. 6) the value of aposition in an array of memory storing the age categories. The exampleweight calculator 304 assigns a weight (w) to the audience memberrecords 202 in the age category selected at block 406 based on aquantity (n_(g)) of audience member records 202 in the training set thatbelong to the same age category (block 408). An example method ofassigning the weight (w) to the selected audience member record 202 isdisclosed below in relation to FIG. 5. In some examples, the weightcalculator 304 executes instructions that cause an arithmetic logic unit(e.g., the arithmetic logic unit (ALU) 634 of FIG. 6) to calculate theweight (w). The example weight calculator 304 determines whether thereis another age category to select (block 410). In some examples, theweight calculator 304 executes instructions that cause the memorymanagement unit 636 to determine whether the last position of the memoryarray storing the age categories has been reached. If there is anotherage category to select, program control returns to block 406 to selectanother age category. In some examples, the weight calculator 304selects the age categories in chronological order. For example, if thefirst age category selected by the weight calculator 304 was the 7-13age category, the weight category may select the 14-18 age category.Otherwise, if there is not another age category to select, programcontrol advances to block 412.

At an initial node, the example model builder 306 splits the audiencemember records 202 in the training set into child nodes based on aninitial pair of an attribute 204 (FIG. 2) and a value threshold (block412). For example, the model builder 306 may select the initial pair ofthe attribute 204 and the value threshold based on the pair of theattribute 204 and the value threshold that has a maximum entropy value.In some examples, the model builder 306 executes instructions that causethe memory management unit 636 to (i) load the value threshold into afirst register (e.g., a register of the registers 635 of FIG. 6) and thevalues corresponding to the attribute 204 of the audience member records202 into second registers (e.g., registers of the registers 635 of FIG.6), and (ii) cause the arithmetic logic unit 634 to compare the value inthe first register to the values in the second registers. The examplemodel builder 306 selects one of the child nodes (block 414). In someexamples, the model builder 306 executes instructions that cause thememory management unit 636 to load a third block of memory storing theaudience member records 202 assigned to the selected child node intocache memory (e.g., the local memory 613 of FIG. 6). For the child nodeselected at block 414, the example model builder 306 calculates theeffective quantity (n_(e)) of the audience member records 202 assignedto the child node (block 416). For example, the model builder 306 maycalculate the effective quantity (n_(e)) of the audience member records202 based on Equation 4 above. In some examples, the model builder 306executes instructions that cause the arithmetic logic unit 634 tocalculate the effective quantity (n_(e)) of the audience member records202 of from the audience member records 202 loaded into the cache memory613.

The example model builder 306 determines whether the effective quantity(n_(e)) calculated at block 416 satisfies a minimum leaf size (m_(ls))(block 418). In some examples, the model builder 306 determines that theeffective quantity (n_(e)) calculated at block 416 satisfies a minimumleaf size (m_(ls)) if Equation 5 above is true. In some examples, themodel builder 306 executes instructions that cause the arithmetic logicunit 634 to compare the effective quantity (n_(e)) stored in the firstregister to the minimum leaf size (m_(l)s) stored in the secondregister. If the effective quantity (n_(e)) calculated at block 416satisfies the minimum leaf size (m_(ls)), the example model builder 306designates the child node as an intermediate node (block 420). In someexamples, the model builder 306 executes instructions that cause thememory management unit 636 to modify a location in the third block ofthe memory to store a value indicative of being the intermediate node.The example model builder 306 then splits the intermediate node intoadditional child nodes based on another attribute 204 and acorresponding value threshold (block 422). In some examples, the modelbuilder 306 executes instructions that cause the memory management unit636 to allocate a block of memory for each of the newly created childnodes. Otherwise, if the effective quantity (n_(e)) calculated at block416 does not satisfy the minimum leaf size (m_(ls)), the example modelbuilder 306 designates the child node as a terminal node (block 424). Insome examples, the model builder 306 executes instructions that causethe memory management unit 636 to modify a location in the third blockof the memory to store a value indicative of being the terminal node.The model builder 306 determines if there are more child nodes (block426). In some examples, the model builder 306 executes instructions thatcause the arithmetic logic unit 634 to determine if memory blocksassociated with the nodes of the age correction model 142 include thevalue indicative of being the child node. If there are more child nodes,the example model builder 306 selects one of the child nodes (block414). In some examples, the model builder 306 executes instructions thatcause the memory management unit 636 to load a block of memorycontaining the child node into cache memory 613. Otherwise, if there areno more child nodes, the example model builder 306 validates the agecorrection model 142 (block 428). In some examples, to validate the agecorrection model 142, the model builder 306 applies the audience memberrecords 202 in the validation set to the age correction model 142. Insome such examples, the model builder 306 compares the expected outputof the age correction model 142 (e.g., the age categories indicated bythe terminal nodes to which the audience member records 202 areassigned) to the actual output of the age correction model 142 (e.g. thetrue age associated with the audience member records 202). In someexamples, the model builder 306 executes instructions that cause thearithmetic logic unit 634 to calculate differences between registerscontaining values of the expected output of the age correction model 142and registers containing values of the actual output of the agecorrection model 142. The example program of FIGS. 4A and 4B then ends.

FIG. 5 is a flow diagram of example machine readable instructions thatmay be executed to implement the example weight calculator 304 of FIG. 3to assign weights to the audience member records 202 (FIG. 2) in thetraining set. Initially, the example weight calculator 304 determineswhether the quantity (n_(g)) of audience member records 202 associatedwith the selected age category satisfies (e.g., is greater than or equalto) the first weighing threshold (th_(n)) (block 502). If the quantity(n_(g)) of audience member records 202 associated with the selected agecategory satisfies the first weighing threshold (th_(n)), the exampleweight calculator 304 assigns a neutral weight (e.g., one, etc.) to theaudience member records 202 associated with the age category (block504).

If the quantity (n_(g)) of audience member records 202 associated withthe selected age category does not satisfy the first weighing threshold(th_(n)), the example weight calculator 304 determines whether thequantity (n_(g)) of audience member records 202 associated with theselected age category satisfies (e.g., is less than or equal to) thesecond weighing threshold (th,r) (block 506). If the quantity (n_(g)) ofaudience member records 202 associated with the selected age categorysatisfies the second weighing threshold (th_(vl)), the example weightcalculator 304 assigns the maximum weight (w_(max)) to the audiencemember records 202 associated with the age category (block 508).Otherwise, if the quantity (n_(g)) of audience member records 202associated with the selected age category does not satisfy the secondweighing threshold (th_(vl)), the example weight calculator 304 assignsa weight (w) between the maximum weight (w_(max)) and the neutral weightto the audience member records 202 associated with the age category(block 510). In some examples, the weight calculator 304 determines theweight (w) to assign to the audience member records 202 associated withthe age category based on Equation 3 above. The example program of FIG.5 then ends.

FIG. 6 is a block diagram of an example processor platform 600 capableof executing the instructions of FIGS. 4A, 4B, and/or 5 to implement theage modeler 128 of FIGS. 1 and 3. The processor platform 600 can be, forexample, a server, a personal computer, a workstation, or any other typeof computing device.

The processor platform 600 of the illustrated example includes aprocessor 612. The processor 612 of the illustrated example is hardware.For example, the processor 612 can be implemented by one or moreintegrated circuits, logic circuits, microprocessors or controllers fromany desired family or manufacturer. The example processor 612 includesan arithmetic logic unit 634 to perform arithmetic, logical, andcomparative operations on data in registers 635. The example processoralso includes a memory management unit 636 to load values between localmemory 613 (e.g., a cache) and the registers 635 and to request blocksof memory from a volatile memory 614 and a non-volatile memory 616. Theexample processor 612 is structured to include the example recordgenerator 302, the example weight calculator 304, and the example modelbuilder 306.

The processor 612 of the illustrated example is in communication with amain memory including the volatile memory 614 and the non-volatilememory 616 via a bus 618. The volatile memory 614 may be implemented bySynchronous Dynamic Random Access Memory (SDRAM), Dynamic Random AccessMemory (DRAM), RAMBUS Dynamic Random Access Memory (RDRAM) and/or anyother type of random access memory device. The non-volatile memory 616may be implemented by flash memory and/or any other desired type ofmemory device. Access to the main memory 614, 616 is controlled by amemory controller.

The processor platform 600 of the illustrated example also includes aninterface circuit 620. The interface circuit 620 may be implemented byany type of interface standard, such as an Ethernet interface, auniversal serial bus (USB), and/or a PCI express interface.

In the illustrated example, one or more input devices 622 are connectedto the interface circuit 620. The input device(s) 622 permit(s) a userto enter data and commands into the processor 612. The input device(s)can be implemented by, for example, an audio sensor, a microphone, acamera (still or video), a keyboard, a button, a mouse, a touchscreen, atrack-pad, a trackball, isopoint and/or a voice recognition system.

One or more output devices 624 are also connected to the interfacecircuit 620 of the illustrated example. The output devices 624 can beimplemented, for example, by display devices (e.g., a light emittingdiode (LED), an organic light emitting diode (OLED), a liquid crystaldisplay, a cathode ray tube display (CRT), a touchscreen, a tactileoutput device, a printer and/or speakers). The interface circuit 620 ofthe illustrated example, thus, typically includes a graphics drivercard, a graphics driver chip or a graphics driver processor.

The interface circuit 620 of the illustrated example also includes acommunication device such as a transmitter, a receiver, a transceiver, amodem and/or network interface card to facilitate exchange of data withexternal machines (e.g., computing devices of any kind) via a network626 (e.g., an Ethernet connection, a digital subscriber line (DSL), atelephone line, coaxial cable, a cellular telephone system, etc.).

The processor platform 600 of the illustrated example also includes oneor more mass storage devices 628 for storing software and/or data.Examples of such mass storage devices 628 include floppy disk drives,hard drive disks, compact disk drives, Blu-ray disk drives, RAIDsystems, and digital versatile disk (DVD) drives.

Coded instructions 632 of FIGS. 4A, 4B, and 5 may be stored in the massstorage device 628, in the volatile memory 614, in the non-volatilememory 616, and/or on a removable tangible computer readable storagemedium such as a CD or DVD.

From the foregoing, it will appreciate that examples disclosed hereinallow generation of an age correction model that is representative ofaudience members in age categories that are underrepresented in apanelist household population. Furthermore, examples disclosed hereinallow for generating probability density functions without consumingadditional memory and processor resources to infer probabilitiesreflecting underrepresented ages in the probability density functions.The example probability density functions are based on the audiencemember records assigned to the respective terminal node that include theunderrepresented age(s). This allows the AME, for example, to creditmedia and/or calculate more accurate ratings that include the ages thatare underrepresented in the panelist population without consumingadditional memory and processor resources to recruit and monitorpanelists the difficult to recruit age categories.

Furthermore, examples disclosed herein solve a problem specificallyarising in the realm of computer networks in the Internet age. Namely,as a large variety of media is increasingly accessed via the Internet bymore people, the AME cannot rely on traditional techniques (e.g.,telephone surveys, panelist logbooks, etc.) to measure audiences of thevariety of the media. Additionally, because the database proprietor dataused to measure the audiences is self-reported, the database proprietordata may include inaccuracies that cannot be corrected or verified bythe AME through the traditional techniques. For example, because theaudience member interacts with the database proprietor in a firstInternet domain, the AME in a second Internet domain, and the media in athird Internet domain, the AME cannot verify the demographic information(e.g., true age, etc.) of the audience member using the traditionaltechniques (e.g., a survey, etc.). Examples disclosed herein solve thisproblem by using demographic information and activity data of knownaudience members (e.g., the panelists) that interact with the databaseproprietor in the first Internet domain and the AME in the secondInternet domain to correct the demographic information of unknownaudience members (e.g., audience members that interact with the databaseproprietor in the first Internet domain without interacting with the AMEin the second Internet domain).

Although certain example methods, apparatus and articles of manufacturehave been disclosed herein, the scope of coverage of this patent is notlimited thereto. On the contrary, this patent covers all methods,apparatus and articles of manufacture fairly falling within the scope ofthe claims of this patent.

What is claimed is:
 1. A processor system, comprising: memory in circuitwith a processor; a memory management unit (MMU) to: store audiencemember records in a first block of the memory, the audience memberrecords including attribute-value pairs representative of databasesubscriber activity data of corresponding audience members subscribed toa database proprietor; split the audience member records from an initialnode into child nodes based on comparisons of first ones of theattribute-value pairs of the audience member records to a first valuethreshold; load, into a cache memory of the processor, a portion of theaudience member records corresponding to a first one of the child nodesstored in a second block of the memory; and an arithmetic logic unit(ALU) to: compare first and second registers of the processor, the firstregister including a quantity of ones of the audience member recordsthat are in the first child node, and the second register including aminimum leaf size; the MMU to: when the ALU determines that the quantityof the ones of the audience member records in the first child node doesnot satisfy the minimum leaf size, store a terminal node value in thesecond block of the memory to indicate the first child node as aterminal node associated with one age category; when the ALU determinesthat the quantity of the ones of the audience member records in thefirst child node satisfies the minimum leaf size, store an intermediatenode value in the second block of the memory to indicate the first childnode as an intermediate node, and split the first child node into secondchild nodes to be stored at corresponding third blocks of the memory,the ones of the audience member records in the first child node to be:(1) assigned to corresponding ones of the second child nodes based oncomparisons of second ones of the attribute-value pairs of the audiencemember records to a second value threshold, and (2) processed further tocreate terminal nodes; and generate an age-correction model based on theterminal nodes to facilitate correcting a database subscriber agecharacteristic associated with a media impression that is logged by aserver of the database proprietor based on a network communicationtransmitted by a client device to report to the server of the databaseproprietor that media was accessed via the client device.
 2. Theprocessor system as defined in claim 1, wherein the MMU is to split theaudience member records into the child nodes based on comparisonsperformed by the ALU between the first threshold value in a thirdregister and values of the first attribute-value pairs in fourthregisters.
 3. The processor system as defined in claim 1, wherein theMMU is further to assign a weight to each audience member record, theweight being based on a quantity of audience members in a same age groupas the audience member record.
 4. The processor system as defined inclaim 3, wherein the MMU is to store an array of age categories in afourth block of the memory and to load a fifth register with a value ofa position in the array of age categories, when the value in the fifthregister equals the last position in the array of age categories, theMMU is to determine that all the weights have been assigned.
 5. Theprocessor system as defined in claim 1, wherein the MMU is further toorganize the audience member records into a training set and avalidation set, the training set to be stored in the first block of thememory and the validation set to be stored in a fourth block of thememory, the ALU to apply the audience member records in the validationset to the age correction model to validate the age correction model. 6.The processor system as defined in claim 5, wherein the ALU is to applythe audience member records in the validation set to the age correctionmodel by calculating a difference between registers containing values ofan expected output of the age correction model and registers containingvalues of an actual output of the age correction model.
 7. Anon-transitory computer readable storage medium comprising machinereadable instructions that, when executed, cause a processor system toat least: store audience member records in a first block of memory, theaudience member records including attribute-value pairs representativeof database subscriber activity data of corresponding audience memberssubscribed to a database proprietor; split the audience member recordsfrom an initial node into child nodes based on comparisons of first onesof the attribute-value pairs of the audience member records to a firstvalue threshold; load, into a cache memory of a processor of theprocessor system, a portion of the audience member records correspondingto a first one of the child nodes stored in a second block of thememory; and compare, with an arithmetic logic unit (ALU) of theprocessor system, first and second registers of the processor, the firstregister including a quantity of ones of the audience member recordsthat are in the first child node, and the second register including aminimum leaf size; when the quantity of the ones of the audience memberrecords in the first child node does not satisfy the minimum leaf size,store a terminal node value in the second block of the memory toindicate the first child node as a terminal node associated with one agecategory; when the quantity of the ones of the audience member recordsin the first child node satisfies the minimum leaf size, store anintermediate node value in the second block of the memory to indicatethe first child node as an intermediate node, and split the first childnode into second child nodes to be stored at corresponding third blocksof the memory, the ones of the audience member records in the firstchild node to be: (1) assigned to corresponding ones of the second childnodes based on comparisons of second ones of the attribute-value pairsof the audience member records to a second value threshold, and (2)processed further to create terminal nodes; and generate anage-correction model based on the terminal nodes to facilitatecorrecting a database subscriber age characteristic associated with amedia impression that is logged by a server of the database proprietorbased on a network communication transmitted by a client device toreport to the server of the database proprietor that media was accessedvia the client device.
 8. The non-transitory computer readable storagemedium as defined in claim 7, further including instructions that, whenexecute cause the processor system to split the audience member recordsinto the child nodes based on comparisons performed by the ALU betweenthe first threshold value in a third register and values of the firstattribute-value pairs in fourth registers.
 9. The non-transitorycomputer readable storage medium as defined in claim 7, furtherincluding instructions that, when execute cause the processor system toassign a weight to each audience member record, the weight being basedon a quantity of audience members in a same age group as the audiencemember record.
 10. The non-transitory computer readable storage mediumas defined in claim 9, further including instructions that, whenexecuted cause the processor system to store an array of age categoriesin a third block of the memory and to load a fifth register with a valueof a position in the array of age categories, when the value in thefifth register equals the last position in the array of age categories,determine that all the weights have been assigned.
 11. Thenon-transitory computer readable storage medium as defined in claim 7,further including instructions that, when executed cause the processorsystem to organize the audience member records into a training set and avalidation set, the training set to be stored in the first block of thememory and the validation set to be stored in a fourth block of thememory, apply, with the ALU, the audience member records in thevalidation set to the age correction model to validate the agecorrection model.
 12. The non-transitory computer readable storagemedium as defined in claim 11, wherein the audience member records inthe validation set are applied to the age correction model bycalculating, using the ALU, a difference between registers containingvalues of an expected output of the age correction model and registerscontaining values of an actual output of the age correction model.